Apparatus for testing water



May 6, 1941- L. G. DANIELs 2,241,121

APPARATUS FOR TESTING WATER Filed July 23, 1938 8 Sheets-Sheet 1 7J 166 :L 67 arf 169 F5- 20a 57 1967") A 7 1 64 l 201 16? 204( 163 Y 09 ze! 1f@ 'M3 /ZZ /196 l 211 Z9 19a f i az :i: 2 fu .(78 33 68 zee v 4 4! J4' 1)61 1W /ZZJL I T'P /26-,6 221 `2zz n 225 7 17a A 227 /163 l Zwf/ 1361 i86- Ely 11, I/ i la a 4 et?? @of J Z May 6, 1941.

L. G. DANIELS APPARATUS FOR TESTING WATER Filed July 2:5, 193s a sheets-sheet 2 ZJ Y WWWWWIm/WWWMWWWWWWW/ May 6, 1941.

Filed July 23, 1938 -8 Sheets-Sheet 3 May 6, 1941.

| G. DANlELs APPARATUS FOR TESTING WATER Filed July 25, 195s 8 Sheets-Sheet 4 li n May 6,l 1941- L. G. DANlELs 2,241,121

APPARATUS FOR TESTING WATER FiledJuly 25, 1938 8 VShee1'.s-Sheel'. 5

May 6, 1941. 1 L, G, DANLS 2,241,121

APPARATUS FOR TESTING WATER Filed July 23, 1938 8 Sheets-Sheet L. G. DANIELS APPARATUS FOR TESTING WATER May 6, 1941.

s sheets-sheet v Filed July 23, 1958 ffl/lll *Ey @M May 6, 1941- L. G. DANxELs .2,241,121

I Y APPARATUS FOR TESTING WATER Filed July 23, 1958 8 Sheets-Sheetv 8 Patented May 6, 1941 APPARATUS FOR TESTING WATER Lee G. Daniels, Rockford, Ill., assignor to YElgin Softener Corporation, Elgin, Ill., a corporation of Illinois Application July 23, 1938, Serial N0. 220,906

' s claims. A,(cl. 23-253) This inventiony relates to testing devices and more particularly to a device for testing for a predetermined amount of either hardness or softness in the water, and for emitting a signal of some kind, such as a visual or audible signal,

or for initiating the cycle of operation of Vany well known type of water softener, for example, by closing the switch or switches thereof-which are normally closed manually. The device also finds use in the proportioning4 of water and has other uses which are apparent to those skilled in the art. .V

An object of the invention is the provision of a generally improved device of the character described.

I have also aimed to provide a tester wherein improved means are provided for indicating the presence of hardness in the water and for responding to the absence thereof.

Another object of the invention is the provision of a tester having improved means for selecting a test portion, for adding a soap solution thereto, for producing agitation therein to develop a foam, and for indicating the presence or absence of a predetermined amount of test foam or suds on the test sample. l

Another object of the invention is the provision of a tester wherein the presence or absence of a certain amountof hardness in the water is indicated by the presence or absence of a certain amount of foam or suds on a test portion, and the provision therein cf improved means for responding to the presence or absence of a certain amount of foam.

A still further object of the invention is the provision of an improved vmethod for testing water for hardness or the absence of hardness, which includes the step of seating a light oat on the top of the foam for the purpose of obtaining the desired test result.

Other objects and advantages will appear from the following description and the accompanying drawings, in which Figure 1 is a diagrammatic showing of a tester embodying my invention;

Fig. 2 is a chart showing the sequence of op.- eration of the device; f

Fig. 3 is a top view of a preferred embodiment of the invention;

Fig. 4 is a front view thereof;

Fig. 5 is a section on the line 5 5 of Fig. v3;

Fig. 6 is a rear view thereof; Fig.f'l is a vertical section through the timing motor -with the. cover removed therefrom;

Fig. 8 is a section on the line 8--8 of Fig. 3 showing the driving motor and the soap pump;

Fig. 9 is a section on the line 9--9 of Fig. 5 showing the pipe connections to the soap pump;

Figs. 10 and 11 are sections on the lines `lil-iii and lI-ll of Fig. 5;

Fig. 12 is a view on the line |2-l2 of Figl 5 showing the top of the test chamber, and

Figs. 13 and 14 are fragmentary side views of the test chamber and associated switch mechanism showing moved positions thereof.

The invention contemplates a testing device adapted to be connected to a water supply and to conduct tests on the water or other liquid in succession, and adapted to perform some operation such as the closing of the circuit for controlling or operating some other device such as a signal, a bell, a motor or the like in response either to a negative or a positive test for hardness. In the present embodiment of the invention, a test chamber is provided having drain, overflow, inlet valves and a test bell in the form of an inverted cup or float. At the beginning of the cycle of the test the drain is closed, the overflow is closed, the inlet is closed, and the oat is down resting against the surface of the material in the chamber. During the first operating interval, the drain is opened, the overflow is opened and the inlet is opened. During the next operating interval time is allowed to lapse during which period liquid flows through the chamber for the purpose of ushing the same. In the next operating interval the drain is closed so that liquid ows into the chamber filling the same and overflowing through the overflow for a short interval for washing out and cleaning the chamber. Thereafter the inlet is closed and the liquid is allowed to pass out through the overflow to the level of the overow, thus retaining a measured amount of liquid in the chamber. The overflow is thereupon closed and a measured quantity of soap is injected into the chamber. This mixture of soap and liquid is then agitated and aerated for the purpose of producing a froth or suds. Thereafter a short period of time is allowed to elapse to give time for the foam to subside. With hard water a temporary foam may be produced by the Violent agitation, and by permitting this dwell the froth will break and disappear. With soft water the froth will remain as what is known as a permanent foam. Thereafter the iioat is set down thereon. If the water was soft, the froth will support the fioat in an elevated position, but if `no froth or suds, or only a small amount is present the float will the signal or perform other functions in response to the position of the oat, in this instance testing, in effect for the presence or appearance of f Means are also providedfor causing the reversal of operation, that is, causingthe cir-v hardness.

cuit to be closed when the float occupies the upper position and open at its lower position so as to perform a test for softness as distinguished l from a test for hardness in the water.

Referring to Figs. l, 3 and 4, particularly, the

present embodiment of the invention includes a frame designated generally `by the numeral I5 and adapted to support and carry a major part of the operative mechanism. In this instance the frame I5 is seated on a base VI6. .The base I6 has side walls |1, a back |8, and.a top I9 providing an enclosure for a major part of the operatingmechanismhe frontof the case formed by the base and walls being closed by a window 2| of glass, permitting inspection of the .mechanism. Positioned on the base I6 is a tank 22, in this instance adapted to' hold soap solution though suitable for other reagents which may be desirable in conducting the tests. This tank. has

in this instance glass side walls 23 and a top 24 1 provided with a capped opening 25 for lling the same and a tube 26 extending to a point adjacent thebottom of the tank for the purpose of deliver? ing the soap solution therefrom, as will presently more fully appear. A test ,chamberA designated generally by the numeral 21 is in this instance formed in the top of the frame l5 andhas a glass front panel 23 secured in position by means of a retainer and screws 29. Water or other liquid to be tested is conductedV to the .chamber 21 through a pipe 3|, a valve 32 and an inlet pipe 33 (Figs, 5 and 6).. The lower end of the chamber 21 has a manifoldwell 34 connected` to drain through a pipe 35 and communicating with the chamber 21 by means of internally threaded bores 36, 31 and 33. Threaded into the bore 31 is a safety overflow tube 36 which extends upwardly into the chamber and is designed to at all times permit overow when the level of the liquid in the chamber 21 reaches an excessive height andthereby limit the upper level of liquid in the chamber. A second overflow is provided by'a tube 4| threaded into the bore 38 as shown at 42 and having an upper end 43 of reduced external diameter, the upper end of the overflow 4| being lower than the upper end of the overflow 39, the overflow 4| serving to determine the amount of the sample and to cause a measured quantity of the liquid to be retained in the chamber. A closure 44 is provided for the upper vend ofthe overiow 4| .and has a rubber seat 45 seating against the ,upper end of the overflow `tube to seal the same. The closure 44 is actuated in timed relation with the remainder of the mechanisrn by means presently to be described. A thimble 46 is threaded into the bore 36 and has a shoulder 41 and gasket 48 for sealing the junction therebetween. The upper end of the thimble is positioned on a` level slightly below the lower surface of the chamber 21'and'servesl as a drain fio for the chamber. A closure 49 having a resilient seat 5| functions to close the upper end of the drain port in timed relationship with the operation of the mechanism as will presently be described.

In the operation of the device water passes to the chamber through the pipe 3| and passes upward through the bottom of the chamber and is discharged into the chamber through a nozzle 52 having an oriiice 53 disposed sidewise so as to give the entering water a swirl around the chamber and thus pick up any sediment or precipitate which may be present therein to flush the same from the chamber.

Soap solution enters the chamber by way of a tube 54. The tube 54 has a ball check valve 55 positioned therein adapted to prevent return iiow o`f..solution and is connected to a pump cylinder 56 from which soap solution is supplied to the line 54 to be discharged into the chamber 21. Soap Solution is drawn into the pump cylinder 56 through the tube 26 which likewise has a bail check valve 51 designed to prevent return flow from the' pump cylinder to the reservoir 22. The pump cylinder 56 has a chamber 58 adapted normally to be lled with soap solution. The cylinder is supported on the frame |5 through a bracket 59'which is attached to a bracket 6| by .means of ,screws .62, the .bracket 6| in Vthis instance being integral with the frame |5. Interposed between the cylinder 56 and the bracket 59 is a resilient diaphragm 63 of rubber or similar 'material and a spacer block 64 having a central opening 65 for the reception of a plunger 66 carried on a reciprocable stem 61. When the plunger 66 is moved to the right facing Fig. 8, the diaphragm 63 is moved into the chamber 58 displacing a part of the soap solution outward through the tube 54 and into the test chamber, whereas when the stem 61 is released, the plunger 66 is returned by action of the diaphragm 63 which moves out of the chamber 56 drawing soap solution into the chamber 58 past the check valve 51.

In order to agitato or mix and aerate the contents of the test chamber, an agitator 63 is provided carried on a shaft 69vdepending into the chamber and driven by'aV small electric motor designated generally by the numeral 1|, the motor being controlled in its periods of operation by timing and control mechanism which will presently be described. Operation of this motor serves to mix the water and soap solution and to create a froth or foam therein when the water is soft, the test being analogous to the conventional soap test.

In order to actuate mechanism in response to the presence or absence of a predetermined amount of perinanent'foam or suds on the water, I employ an inverted cup-shaped float designated generally by the numeral 12. I have found that one satisfactory type of float consists of a hemisphere of Celluloid of relatively thin cross-section (see Fig. 5). This is supported at its apex on a lever 13 pivotally supported on the frame |5 by means of ears 14 and needle pointbearings 15, the support being intermediatethe ends of the lever 13. The opposite end .of the lever 13 has a roller 16 positioned thereon adapted to engage a cam designated generally by the numeral 11 carried on a shaft 18 driven by a motor 19 enclosed within a housing 8|. The cam 11 has a notch 82 provided at one sideV with an angularly disposed surface 83 and at the `opposite side with an arcuate portion 84|,V the `portion 84 engaging the .roller 16 to. gradually :rotate .the nlevert` 13."ad .lift the floati to its upper position dendby the `cam surface 85. The angular portion 83 permits of. gradual release offthe roller 16 and movement 'of the end of the lever 13` into the notch 82 and a consequent gentle lowering of the iioat 12. The .cam 11 rotates in timed relation with the remainder of the mechanism so that uponthe completion of the agitation ofthe contents of the chamber 21 and a short rest period, the iioat 12 is lowered. The float and lever 13 are so counterbalanced that if foam persists on the top of the solution in the test chamber,the float will remain in an upper position supported by the foam. Such a condition exists when the water in .the test chamber is soft.v .On the other hand, when the water therein ishard beyond a predetermined degree as determined by the setting of the `stationary contacts andthe adjustment of the pump, the soap will be insufficient totproduce astable foam and consequently the float 12 will move on downward to the4 position shown in Fig. 5.

The closures 44 and 49, the inlet valve 32, and the reagent stem 61 are actuated by a lever.v 86 inthe nature of a bell crank lever pivotally supported intermediate its ends on the frame I5 `as shown at 81. One of the arms 88 thereof carries anadjustable screw 89 adapted to contact the .stem 61 and actuate the same. The opposite leg 9| thereof extends over the test chamber 21 and is adapted to engage ladjustable fingers 92 and 93 supported on stems 94 and 95 which carry the closure members 44 and 49, as shown in Figs. 10 and 11. ing arm 96 having openings 91 and 98 for sliding reception of the stems 94 and 95. The stems also have a lower sliding support as shown at 99 and Springs |02 and |03 act between the arm 96 and the fingers 92 and 93 to normally urge the stems to the closed position. The lever arm 9| has an extreme end portion |04 adapted to engage the end of a valve lever which has pivotal connection with the stem |06 of the valve 32 and is fulcrumed at |01 on a link |08 pivotally supported on a pin |09 attached to the frame I5v whereby upon rotation of the arm 9| the valve lever |05 is rotated about its pivotal supportl |01, the link |08 permitting of lateral adjustment of the lever. A spring acts between the valve lever |05 and the frame l5 nor-` mally urging the valve stem |06 to the closed position of the valve.

Driving and control units indicated generally by the numeral ||2 and |3, respectively, are provided for controlling the sequence of operation of the device and for driving the various elements thereof. The unit ||2 includes the motor 19 and the casing 8| which encloses the gearing, contacts and contact cams. Likewise, the unit |3 has a casing I4 which encloses the motor, gearing and contact cams of this unit. The unit ||2 is herein designated as the operating or driving unit, whereas the unit ||3 is designated as the timing or control unit. The driving unit ||2 includes the motor 19 having a rotor ||5 carrying a pinionV 6 which drives a gear ||1 having a pinion ||8 meshing with an idler gear I9, which in turn has a pinion |2| ,which meshes with an idler |22 also carrying a pinion |23, which inturn drives agear |24 attached to a cam shaft |29. The cam 11 is fixed on the cam shaft |29 outside the casing of theunit, and the Vshaftdcarries,cams |,3,||32, |33, |34 and |35 Wthinl-the casing adapted to actuatev spring pressed The frame |5 has an upwardly extend- -f movable contacts |36 to |39, inclusive. The cam |34ffunctions to' actuate a psh'and pull rod |4| pivotally attached to the lever 86 as shown at |42 for .the purpose of actuatingthe lever 86 which controls the operation of the inlet valve, theY drain valve, the overflow valve and the reagent pump as heretofore described. The push rod .|,4| has a cam follower |43 to which are attached spaced rollers |44 and |45 which bear against opposite sides of the cam |34. The follower has a depending sleeve |46 within which the upper end of the rod |4| is received for slid; ing movement, the upper end of the rod having a flangedhead as shown at |41. The rod carries a transverse pin |48 which is slidably received in slots |49 to allow a certain amount of lost motion between the rod and the sleeve |46. Positioned within the sleeve is a spring |5| acting between the inner end of the sleeve and the iiange |41. 'Ihrough this arrangement it will be seen that when the cam follower moves downward facing Fig. 8 rotating the lever 86 in aclockwise direction, the follower may continue to move down after the lever has reached the end of its movement, the cross pin |48 permitting continued movement of the sleeve |46 and the application ofspring pressureto the end of the push rod |4 I as a result of continued downward movement of the follower.` The movable contacts |36 to |39 cooperate with stationary contacts |52to |55, inclusive, to open and close circuits for the controlof the device, as will presently appear.

The timing unit I3 has a timing motor |56, in this instance of the self-starting synchronous type which drives a cam shaft |51 through suitable gearing |58. The gearing |58 may be changed as desired in order to produce a desired -time cycle. Cams |59, |6|, |62, |63 and |64 are positioned on the shaft |51 and serve to actuate movable contacts |65 to |69, which contacts are spring pressed against the cams. The movable contacts cooperate with stationary contacts |1| to |15 to function in the control of the device.

Attention is now directed more particularly to the diagrammatic showing and wiring diagram of Figure 1, and to the diagram of Fig. 2. The latter diagram shows the relative points at which the various cams open and close their respective contacts and actuate the various instrumentalities and the degree of movement during the driving periods of the motor 19. Power is supplied for operation of the device through a transformer |16 from the secondary of which power is supplied to the timing motor |56 by way of a conductor |11, stationary contacts |18, of a relay designated generally by the numeral |19, bridging contacts |8| of the relay, a conductor |82, a conductor |83, a manually operated master switch |84, a time control switch |85, a conductor |86, a conductor |81, the motor |56, and aconductor |88 back to the secondary of the transformer. The time operated switch is optional, but may in many instances be desirable for the purposeof keeping the tester in operation during certain working hours, and in terminating the operation of vthe tester during other hours when there is only a small draw of water, as for example, in a laundry. In the absence of the time switch |85 the tester will remain in operation repeating cycle after cycle so long as the master switch |84 is closed. During the initial movement of the timing motor |56, after the closing of switch |84, the cam |59 rotates suiiciently to close the contacts |65 and |1|, thus establishing' circuit through the motor |56` by way of the conductor |11, the contacts|18 rand |8|,"the conductor |82, a conductor |89, thecontacts |1| and |56, a conductor |9|, a conductor |92, the conductor |81, the motor |56 and conductor |68. This will maintain the contacts |65 and |1| closed throughout a complete revolution of the shaft '|51 whereby the test cycle will always be completed regardless of theopening of switch |84, and the parts will be returned to the test or their initial position. Y

Shortly after the start of the motor |56, that is, after the start 4of a cycle characterized by rotation of the cam |59 out of the position shown in Figure 1, a high spot |95 on the cam |62 causes the contacts |61 and |13-to close, thus energizing the driving motor 19 by way of a circuit including the conductor |11, contacts |18 and |8I, conductors |82 and |83, switch |84, conductor |86, conductor |92, conductors |94and |95, the contacts-'I61 and |13, conductors |96 and |91, contacts |52 and |36, which at this point are closed by the 4cam 3|, a conductor |98, the motor 19, conductor |99 and conductor |88. Thereupon the motor 19 drives the shaft |29 through apart of a revolution somewhat less than 180, as will appear from Fig. 2, or until'the cam I3| permits the opening of contacts |36 and |52. This movement of the shaft |29 causes thecam |32 to close contacts |31 and |53 and the cam |34 to move the push rod |4| downward facing'Figure 1,

thereby lifting the stems 94 and 95 and moving the closures 44 and 49 to the open position to open the drain and the overflow. This movement of the lever 86 likewise lifts the stem |96 of the inlet valve 32 so as to establish a flow of liquid into the chamber 21. Liquid flows through the chamber 21 vfor a short period of time for the purpose of flushing out the lower part of the chamber, the liquid passing out through the drain, the liquid continuing to iiow until the motor |56 rotatesl the cam |6| to a -point where a projection 28| thereon closes contacts |66 and |12. This completes a circuit through the driving motor 19 by way of the conductor |11, contacts |18" and |8|, conductors |82 and |83, switch |84, time contacts |85, conductors |86, |92 and |94, contacts |66 and |12, a conductor 292, a conductor 203, contacts |31 and |53, conductor |98,'motor 19 and conductors |99 and |88. The motor 19 thereupon rotates the shaft |29 until the contacts |31 and |53 are opened by action of the cam |32, whereupon the motor 19 stops. During this movement of the shaft |29 the cam |33 yis brought into position to close contacts |38 and |54 and simultaneously the cam |34 operi ates tolmove the rod |4| and the lever 86 so as to permit closing of the drain valve or closure 49 under the action of the spring |93, keping the inlet valve 32 open and the overflow closure 44 open. Under these circumstances liquid lls the chamber 21 and continues to flow through the chamber causing the upper Walls thereof to be flushed, the excess water owing out through the overow so as toclean the chamber. y This ushing period is terminated by operation of a projection 284 onv the cam V|62 which operates to close the contacts |61 and |13 thereby again energizing the motor 19 by way of a circuit including'conductor |11, contacts |18 and |8I, conductors |82 and |83, switches |84'and |85, conductors |86, |92, |94 and |95, contacts |61- and |13, conductor |96, ac'onductor 285, contacts |38 and |54, conductor-|`98,rmotor 19 and conductor |99, causing the motor 191t'o vdrive` the `vsljiaft 29 'until the circuit thereto is'trokfm` by operation ofthe camf|33` opening contacts |38 and- |54. During'this rotation the cam |34 moves the rod |4| and the lever86 -so-as first to close the inlet valve 32. This interrupts the flow of liquid into .the chamber 21 and permits the liquid-to level and drain through the. overflow to a predetermined level, thus retaining a measured sample ofthe rliquid in the chamber. Continued movement of the lever 86 thereupon permits the closure 4| to close theY overflow under the action of the spring |02.'. As the lever 86 continues to .rotate, the adjustable screw 89 on the Vend 88 of the lever 86 comes into contact with the stem 6.1 of the reagent pump and moves the same toward the right facing. Fig. .8, thereby displacing ya measured quantityof the reagent into the chamber 21 by way of the tube 54. lThe cam |34 and follower |46A are so arranged and positioned that the direction of rotation of the lever 86 is then changed causing the adjustable screw 89 to move back and permitting the stem 61 and plunger 66 to move to the left facing Fig. 8 a slight distance so as to withdraw the pressure on the reagent in the cylinder 58 to prevent drip from the end oi the tube 54. At this point the motor 19 stops under the action of cam 33 as previously ide'- scribed. n

At about the time at which the motor 19 stops, the cam |64 causes contacts |69 and |15 to be closed, thereby energizing agitating motor 1| by way of conductor |88, a conductor 206,` motor 1|, a conductor 291, contacts |69 and |15 and a conductor 288. The agitator motor runs at sufficient speed and for a sufficient length of time t-ofthoroughly mix the soap solution or otherreagent'into the liquid in the chamber 21 and to beat up a copious foam or suds on the topof the liquid in the chamber 21. In this particular instance 35 seconds has been found to be sufficient. The operation of the motor 1| is terminated-by movement of the cam |64 allowing contacts |69 and |15 to open. The parts driven by the motor 19 then remain at rest to allow time for a temporary foam or suds in the chamber 21 to subside, the object being in-this instance to use only what is known as the permanent suds for test purposes. While the usual soap test vfor hardness in water provides that the sudsshall persist for five minutes, it has been found satisfactory for present purposes to make this time delay considerably shorter, in this instance about one-half minute. This is possible because it has been found that where there is any appreciable excessof hardness the major portion of the suds willbreak within a half minute.

At the close of this interval as determined by the action of a projection 299 on cam |6| closing contacts |66 and |12, the motor 19 is energized by way ofa circuit including conductor |11, contacts |18 and 8|, conductors |82 and |83, switches |84 and |85, conductors |86, |92 and |94, contacts |68 and |12, conductor 282, a conductor y2| I, contacts |39 and |55 (closed by means of cam |35 during the previous operation of the motorv 19), conductor |98, motor 19 and conductor I 99. The motor 19 then operates to drive the shaft |29l through a small angularity ory until contacts |39 and |55 are opened Vby action of cam |35. During this rotation the roller 16 of lever 13.moves in along cam facel 83 causing the inverted cup-shaped oat 12 to be gently lowered and released. If any substantial degree offroth o1' suds persists on the top of theliquidlin chamber 21, the oat will remain on top of this suds as shown' in Fig. 14, whereas in the absence of a froth 'the oatwill move down to the positionshownin Fig; 13. i t \f 'I'he lever13, which is preferably of electrically conductive material, hasa screw2|2 forming a,

bindingpost for the connection of an electrical conductor 2| 3connected Vtocontact |1||.A .A contact 2|4 4isgcarried on a piece of insulation *2|5 attached to the top of thevchamber 21 vand is connected by means -of a conductor 2|61toone pole 2|1 of a double` pole switch designated generally by the numeral 2|8. Another pole ofthe switch 2|8 is connected to the relay |19by way of a conductor 2|9, the opposite side Yof the relay being `connected to the conductor |88 by means of a lead 22|. ,The ,lever 13 carries a spring-like or somewhat resilient strip of: con-f ductive material 22|! positioned to engage `contact 2|4 when the oat moves down. in the chamber into the position shownv in Fig. 13 to'establish electrical connection between the contact 2|4 and the lever 13. It will therefore be seen that when the float 12 is lowered by action of the cam 11, if no suds is present orga predetermined minimum amount is present, as determined 4 by the adjustment of the position ofthe contact 2| 4, circuit will be established through the relay, |19 when the cam |63'closes contacts |68 and |1 4, this circuit being by way of the conductor 208, contacts |88 land |14, conductor 2|3,.thel lever 13, contact 2|4, conductor 2I6, switch l2|8,I con-l ductor 2|9, relay |19, conductor 22| and con-v ductor |88. Thereupon the bridging contacts |8| are broken from contacts |18 and serve to close relay contacts 222 completing a circuit through a lamp 223 by way 'of conductor |11, contacts |8| and 222, conductor 224 and^conductor |88. This energizes; the signal lamp 223 andjat the same time breaks'the circuit through the timing motor |56 locking up the system. 'I'hisis the condition which will vobtain when the `device is used in the testing of: water for hardness and when a predetermined hardness appears in :the water. It rwill be seen that during the normal course of the tests when used` with azeolite softener the water entering chamber 21 willY be soft and the soap solution added thereto will cause a permanent froth so that the oat'12 will be held up and the circuit will not be closed through the contact 2|4, and this contact will only be closed whena permanentsuds ceasesto be Vproduced as aV result of a test cycle; y I have provided means for repeating a'` test cycle after therelay'l19has locked up, as described, for the purpose of checking the test if desired. This includes a push button 225 inserted in the circuit of the motor |56` by wayv of a circuit including the conductor |11, contacts |8| and 222, conductor 224; a conductor 226, push button 225, a conductor-22'| conductors |88 vand |81, motor |58 and conductor |88.v 'Ihe `push button 225 is manually held closed'until the motor has rotated a sufficient distance-to open contacts |68 and `|14 Whereupon'the relay` |19 is released breaking the connection between contacts |8| and 222 and making connection bef tween contacts |8| and |18 thereby restoringthe motor circuit previously described; whereuponthe device will pass through a cycle in thel manner heretofore traced. a

The device isalso adaptable for use in the testing of the liquid for theopposite property, or, in other words, for the absence of the propiertyunder consideration. 4In the present example I vhave'described the test operations in which the device is setto operate the relay' |19 ated u-pon the appearance of hardness.

and associated switch contacts upon the appearance of hardness in the water of the sample in chamber 21, the water entering the chamber being normally soft and the relay being actu The device may also be set so that no actuation of the relay occurs When the water entering the chamber is hard but in which the actuation of the `relay occurs when the character of the water changes from hard to soft. This apparatus includes the switch 2 8 which may be manually thrown to asecond position establishing circuit between conductor 2|9 and a conductor 228 which is electrically connected to a binding post 229 supported on a bracket 221| attached to the insulation 2|5 (Fig. 13). A contact strip 232, in this instance consisting of a strip of copper or other electrically conductive material and preferably of light weight, is pivotally sup-1 ported on the bracket 23| by means of a supporting member 233 carried on a pin 234 and having a depending arm 235 adapted to be en` gaged by the end 236 of the binding post 229. The outer end of the strip 232 may be curved as shown at 231 and is positioned in the path of travel of the strip 22|] soy as to make contact therewith in an elevated position of the strip 228. The opposite end of the strip 232 may conveniently extend beyond the supporting member 233 as shown at 238 for the purpose of counterbalancing the strip. It will be seen that the support for the strip 232 is such that the inverted cup-shaped float 12 and the lever 13 may bemoved upward and will rotate the strip 232 when moved beyond the point of contact between the elements. From this description it Will be seen 'that toward the conclusion of a test cycle and after `the contents of the lchamber have been agitated and the time allowed for the suds Vto subside, if temporary, when the float 12 is lowered by action of the cam 11, if the water is Ahard and the suds has completely subsided, the float 12 will pass downward to the position shown in Fig. 13 and contact will be made between` the strip 228 and the contact 2|4. However, the contact 2|4 is dead and no action will result on the relay |19. However, if the water in the chamber is soft a permanent suds results and the oat will stop in the position represented 4in Fig. 14 whereinV electrical connection is established between the strip 228 and the strip 232. Under this condition when the -cam |83 closes the contacts |68 and |14, the. relay |19will be energized breaking connection between relay contacts I 8| and 18 and making connection between relay contacts |8| and.222, thus` energizing thelamp 223 by the previously describedr circuit, which, under these circumstances indicates that the water under test has changed from hard to soft. This type of test is advantageousduring the regeneration of Yconventional zeolite water softeners during the washing-,step thereof, that is, while the brine is being "washed from the bed preparatory to returning the softener to service.

Attention is directed to the fact that the degree of hardness at which the relay |19 will be energized can be set-by adjusting the position of the contactfpoint 2| 4 and the position of the contact strip 232.- Thus by moving the contact 2| 4 upward toward the strip 225 the relay will be actuated at a lesser degree of hardness, and likewise by screwing the binding post 229 outward so as to allow the end 231 of the strip 23| tomove furtherdownward the relay during the test for the absence of hardness will be actuated at a greater degree of hardness.

In using the device in testing water, as for example, the effluent from a/zeolite Water softener, the switch 2| 8 is set in a position to establish contact between the conductors 259 and 2|6 and the inlet valve 32 isrconnected to the softener at a point such that eiiuent water from the softener Will pass thereto'. The manualiy operated switch |34 is then closed. Under these circumstances themotor |56 will begin to run unless the time contact |85 is employed in this cincuit, in which instance the starting of the motor lfwill be dependent upon the setting of this time contact. The tester will then repeat test after test until the water entering the chamber 21 proves to be hard beyond that for which the contact 2|4 and the screw 19 of the reagent pump are adjusted, whereupon the relay` |19 locks up'and the lamp 223 is energized indicating that the softener is in need of regeneration. The operator thereupon conducts the regeneration of the softener manually or where an auto-matic water softener is employed, the conductors leading to the lamp 223 may be em# plcyed to control the motor circuitof the auto- Vmatic softener so as to start the 'regeneration thereof in response to operation of the relay |19. When the regeneration has proceeded to the point at which the brine is being washed from the zeolite bed and preferably when the washing has been carried forward for some time, the switch 2`|8 is moved toestablish contact between conductors 2|9 andi 228, atwhich point the re-l lay |19 is released by the breaking of the circuit between conductors 2|9 and 2|6. Thereupon the tester will proceed through its test cycles until the test Vshows a lack Vof hardness producing constituents in the water in the chamber 21, whereupon the relay will again lock up energizing lamp 223. At this point thesoftener is manually returned to 'service and vthe switch 2|8 is returned to its previous position makingcontact between conductors 2 I9 and 2|'6, the relay E19 being released as a resultof this shift of the switch 2|. The tester thereupon resumes Vits test cycle testing the eiiiuent'from the softener for hardness. u

Attention is directed to the fact that when the relay |19 is actuated the timing motor |56 stops immediately because of the opening of the circuit at the contacts |18. Ihis position -is slightly before the cam |19 permits opening of contacts IE5 and |1|. On the other hand, if the manual switch |34 or the time operated contacts |85 are opened during the progress of a test, Ythe parts will continue through to the end of the cycle, the motor |56` being in this instance stopped by action of the cam |59 in opening contacts |65 and While I have thus described and illustrated a specific embodiment of my invention by way of example, I do not wish to be limited except as required by the prior art and the scope of the ap#v pended claims, in Which` I claim:

1. The combination in an automatic hardness Ytester rfor water of a test chamber, a driving motor, means driven by the motor for introducing a measured sample of Water into said chamber,

Y solution to produce the absence of foam or the presence thereof above the surface ofthe Water depending upon the hardness of the water, a 'oat adapted to seat on the surface of said sample comprising a chambered member defining an vair volume for displacing said sample and froth to support the weight of the oat, means driven by said motor for seating said float against the surface of said sample, and means for emitting a signal in response to the seated position of the oat to indicate the presence or absence of foam.

2. The combination in an automatic hardness tester for water of a test chamber, adriving motor, means driven by the motor for introducing a measured sample of Water into said chamber, a closed reagent system including al pump driven by said motor for adding a predetermined amount of soap solution of definite concentration into said sample, means for agitating said sample and soap solution to produce the absence of foam or the presence thereof above the surface of the water depending upon the hardness of the water, a float adapted to seat on the surface of said sample comprising a chambered member defining an air volume for displacing said sample and froth to support the weight of the oat, means driven by said motor for seating said oat against the sur#- face of said sample, an electrically energizedsignal, contacts positioned to be selectively closed by said float seating means when the float seats in an elevated position on the foam and in a lowered position on the surface of the water, and manually operable means for placing said signal under the control of either of said contacts to render the signal responsive solely to either the a presence or the absence of hardness.

3. The combination in an automatic hardness tester for water of a test chamber, a driving motor, means driven bythe motorvfor introducing a measured sample of Water into said chamber, a

closed reagent system including a pump driven by said motorY for adding a predetermined amount of soap solution of definite concentration into said sample, means for agitating said sample and soap solution to produce the 'absence of foam or the presence thereof above the surface of the Water depending upon the hardness of the water, a float adapted to Seaton the surface of said sample comprising a chambered member defining an air volume for displacing said sample and froth to support the weight of the float, means driven by said motor for seating said oat against the surface of said sample, signal means including a contact positioned to be closed by said float seating means in response to the seated position thereof to indicate the presence or absence of foam, and means for energizing said contact after the closing thereof and after the float reaches its seated position.

4. The combination in an automatic hardness tester for Water of a control motor, an operating motor and an agitating motor, electrical contacts operated by the control motor for starting said operating motor and for starting and stopping said agitating motor, a test chamber having inlet, drain and overiiow valves and a closed reagent system including a closed container and a reagent pump, a lever driven by said operating motor arranged to open and close the drain, overflow and inlet valves and to operate thereagent pump, an

inverted cup-shaped oat adapted to be lowered into said chamber for test' purposes shaped to trap air therein when seated upon the sample and the froth, means driven by the operating motor for lowering said oat to make va test and for lifting said float upon the completion of a test,

said means having a contact thereon, manually adjustable stationary electrical contacts positioned to be engaged by said float contact in either of two operative positions thereof, and a relay arranged to be energized in response to the making of said contact.

5. The combination in an automatic hardness tester for water of a test chamber, a driving motor, means driven by the mfotor for introducing a measured sample of water into said chamber, a closed reagent system including la pump driven by said motor for adding a predetermined amount of soap solution of definite concentration into said sample, means for agit-ating said sample and soap solution to producethe absence of foam or the presence thereof above the surface of the water depending upon the hardness of the water, a float adapted to seat on the surface of said sample comprising a chambered member defining an air volume for displacing said sample and froth to support the weight of the float, means driven by said motor flor seating said float against the surface of said sample, a power circuit for said motor, a controlled circuit, a relay arranged in its deenergized `position to close said power circuit and lopen said controlled circuit, and in the energized position thereof lto open said power circuit and close said controlled circuit, a contact positioned to be closed by said float seating means in response to change in the seated position of said float corresponding to a predetermined change in the hardness of the water to energize said relay to stop the cycle of tests and permanently energize said controlled circuit.

6. Th-e combination in a hardness tester for water of a test chamber, means for washing out the test chamber and for taking a sample of Water therein, means comprising a closed reagent system for ,adding an accurately measured quantity of soap solution of uniform concentration to said sample, means for agitating said sample to produce the presence or absence of la froth on said sample depending upon the hardness therelof, an inver-ted cup-shaped iioat shaped to trap air therein when seated upon the sample and the froth adapted to seat either on the surface of said sample or on the froth of said sample, means for lifting and lowering said float into said chamber, said means including an electrical contact arm, an electrical relay and spaced contacts positioned for engagement by sai-d contact arm to control said relay, an electric motor for initiating the operation of each of said means in timed relation, means under the control of said relay for stopping said motor and energizing an independent circuit in response to energization of the relay, and manually operable means for restarting said control motor.

7. The combination in a Water tester of a test chamber, means for taking samples of water therein for test purposes, an enclosed reagent supply system including an enclosed diaphragm Apump having its inlet constantly submerged in a supply of soap solution for adding a soap solution of diiferent uniform strength .to said sample, means for agtating the sample to produce the presence or absence of a froth thereon in predetermined amount depending upon the hardness of the sample, an inverted cup-shaped float having depending edges for entrapping air therein against the surface of the sample, means for lifting and lowering said float to the surface of said sample to .produce an indication in response to the position of the float, and means for adjusting the stroke of said pump to vary the range of the tester.

8. The combination in a water tester for conducting successive tests on water supplied thereto of a test chamber having an inlet valve, a drain valve, an overflow valve, and an enclosed reagent system including injection means, a single lever positioned for reciprocation in one direction to lopen the inlet, drain and overflow valves, and upon reciprocation in the opposite direction to close said valves and operate said injection means, an inverted cup-shaped float for determining the results of a test in said chamber, la motor, and cam means driven thereby, arranged to periodically reciprocate said lever and to simultaneously raise and lower said float with respect to the chamber to conduct a test.

LEE G. DANIELS. 

